RU2429521C2 - Indicator for assisting user in predicting change in scrolling speed - Google Patents

Abstract

FIELD: information technology. ^ SUBSTANCE: user interface has a scroll function which places the selected part of the medium onto a display area, where the scrolling speed of the user interface varies as far as the scrolling function lasts. The user interface outputs an indicator for warning the user on impending change in scrolling speed. ^ EFFECT: providing the user interface with a device for displaying a medium which is visually larger than the display area. ^ 15 cl, 4 dwg

Description

The invention relates to a system and method for providing indicators to a user that are related to the speed of visual scrolling in a user interface.

Currently, many users make extensive use of computers to implement many applications. Users can interact through the user interface (UI) provided by the application running on the computer with the visual environment displayed by the computer on the display to perform functions on the computer, play games, test simulation or virtual reality environments, and use computer-aided design (CAD) ), viewing the world wide web or otherwise influencing events or images displayed on the screen. UIs represent visual images that describe various visual images of the operating system, applications, etc., implemented on a computer.

A user typically moves a user-driven object, such as a cursor or pointer, across a computer screen to other displayed objects or areas of the screen, and then enters a command to execute the selected item or operation. Other applications or visual environments can also provide user-driven objects, such as a cursor, and contain browsers and other applications displaying web pages and other environments offered on the World Wide Web, CAD applications, video games, virtual reality simulations, etc. In some computer tools, the user may provide input for controlling a three-dimensional (3-D) representation of the environment, as in CAD or three-dimensional virtual reality applications.

User interaction with computer tools and their manipulation are achieved using any of the many types of human-machine interfaces that are associated with the computer that controls the displayed environment. A well-known interface for UIs is the mouse or the ball pointer. The user moves the mouse in a flat workspace to move an object, such as a cursor, on a two-dimensional display screen when directly displayed between the position of the user manipulation and the position of the cursor. This is commonly known as positional control, where the movement of an object directly corresponds to the movement of the user's manipulation. Often the displayed environment is visually greater than the ability to display a computer display. To facilitate viewing the displayed environment, the UI provides the ability to scroll within the environment to see an area of the environment that was not previously displayed.

One drawback of a traditional mouse is the inconvenience of functions such as scrolling the visual environment, as the user must use the cursor to drag the displayed scroll bar. These types of functions are often easier to perform with speed control devices, such as devices that indirectly or abstractly map a user's manipulation of an object, such as pressure-sensitive devices. It is better to perform text scrolling in a window as a task of speed control, since scrolling is not directly related to the position of the mouse on the plane. Similarly, the adjustable speed of the simulated vehicle is suitable for the speed regulation paradigm.

To provide the user with easier control of scrolling with the mouse, the scroll wheel or mouse wheel has been improved and has become very common in computer mice. A scroll wheel is a small finger wheel provided in the mouse in a convenient place, for example between two mouse buttons, which the user can rotate to control the scroll function. Typically, a portion of the wheel protrudes above the upper surface of the mouse, on which the user can move his finger. The wheel typically contains a rubber or other friction surface to allow the user's finger to easily rotate the wheel. A wheel is typically used to scroll through the visual environment without the need for a scroll bar and without selecting a separate scroll control.

Scrolling through the visual environment in the UI is a very common task in electronic devices, including computers, personal digital assistants (PDAs), mobile phones, portable media players, etc. To simplify the following description, unless otherwise indicated, each of these and other devices will be referred to here simply as a computer or computers. For large visual environments, scrolling can be time-consuming, as the user simply has to wait until the target location appears in the visual environment. Therefore, it is convenient for the user to have some means of controlling the scroll speed. This is convenient if the part of the visual environment that passes through the displayed area in a given time is in some way under the control of the user. For example, this is convenient if the number of positions in the displayed list, which for a given time passes through the displayed area, is under the control of the user.

Some applications running on a computer provide scrolling speed in explicit user control. For example, some applications function together with a scroll wheel, for example, by pressing a scroll wheel by a user. After pressing the scroll wheel, the further the user moves the cursor away from the point where the user pressed the scroll wheel, the higher the scroll speed. Further improvement in scroll speed control is provided by Koninklijke Philips Electronics N. V in a device called Superscroll ™, which allows the user to adjust the scroll speed using various levels of pressure on the key that controls the scroll. The stronger the user presses the key, the higher the scroll speed.

To speed up the long-running scrolling, other applications increase the scroll speed one or more times during continuous scrolling after a predetermined period of time, as shown in FIG. Figure 1 shows how the scroll speed, which is represented by varying vertically, varies depending on the duration of the scroll, which is represented by varying horizontally. As the user continues to scroll for a period of time, the scroll speed increases with a certain step from level 1 to level 2. A longer scroll can lead to a repeated increase in the scroll speed from level 2 to level 3. This can continue, or at what - At that time, the maximum scroll speed will be reached. For example, when the user continuously scrolls for more than 10 seconds, the scroll speed can be doubled, etc.

This increase in scroll speed is not always required by the user. It may happen that such an increase in the scroll speed occurs immediately before the target area is reached in the visual environment and the user scrolls outside the target area. In addition, increasing the scroll speed may disorient the user, and the possible scroll speed may be faster than the user requires.

US Patent Document Publication No. 2004/0108992, filed Oct. 20, 2003, entitled "Isotonic-Isometric Haptic Feedback Interface," by Rosenberg, which is incorporated herein by reference, discloses a system for adding sensory feedback, such as shock or vibration. scroll wheels to indicate to the user an event, such as the end of a page or the scroll speed. Accordingly, during scrolling, the user can provide this sensory feedback at a measured speed, which may be proportional to the scroll speed. Similarly, in European patent EP 0880091, filed May 19, 1998, entitled "A Method and an Arrangement for Scrolling Information Presented on a Display of a Mobil Station," by Panu Korhonen, which is incorporated herein by reference, a system for adding auditory feedback to scroll speed.

However, the problem is that practically the user cannot predict when the scroll speed will change (for example, increase, decrease). Using the trial and error method, the user can adapt to a change in speed, but this is tedious, this change in speed can be different in different applications, it needs to be remembered, and this leads the user to mentally count seconds when scrolling. Accordingly, the user can usually only respond to an already changed speed, for example, by stopping scrolling.

The objective of this system is to overcome these and other inconveniences in the prior art.

According to an embodiment of the present system, a user interface of a device for displaying an environment that is visually larger than the display area is provided. The user interface includes a scroll function that places selected portions of the medium on the display area. The scroll speed of the user interface changes as the scroll function lasts. The user interface displays an indicator to warn the user about an upcoming change in scroll speed.

In one embodiment, the user interface displays a first indicator, which is proportional to the scroll speed, and when a change in scroll speed is due, a second indicator is displayed. The second indicator may be proportional to the scroll speed that will be generated if the scroll speed changes. A warning may be at least one of a tactile warning, an auditory warning, and a visual warning. In an identical or another embodiment, the scroll function may be triggered by the first actuation of the scroll, and the scroll speed cannot be changed if the second actuation of the scroll occurs within a predetermined time interval after the termination of the first actuation of the scroll.

In another embodiment, the scroll function may be triggered by the first actuation of the scroll, and the scroll speed may return to a predetermined scroll speed if a second actuation of the scroll occurs within a predetermined time interval after the termination of the first actuation of the scroll.

The following are descriptions of illustrative embodiments that, together with the following drawings, demonstrate the above and additional features and advantages. In the following description, for purposes of illustration and for purposes of explanation only, specific details are set forth, for example, specific architecture, interfaces, methods, etc. However, it will be apparent to those skilled in the art that other embodiments that depart from these specific details will still be within the scope of the appended claims. In addition, for clarity, detailed descriptions of well-known devices, circuits, and methods are omitted so as not to obscure the description of the present invention.

It should be clearly understood that the drawings are included for illustrative purposes and do not represent the scope of the present invention.

Figure 1 shows how the scroll speed of the previous system can vary depending on the duration of the scroll.

2 is an illustrative flowchart illustrating operation in accordance with an embodiment of the present system.

Figure 3 shows how the scroll occurrence rate and the scroll indicator can vary depending on the duration of the scroll according to an embodiment of the present system.

4, an apparatus 400 is shown in accordance with an embodiment of the present system.

According to an embodiment of the present system, an indicator is provided to the user that the scroll speed is about to change. The term speed, as used here, means the content, without limitation, speed (speed) and / or acceleration, unless otherwise specified. Accordingly, a warning is provided to the user that the scroll speed will now be changed, which provides the user with the opportunity, if necessary, to respond to this change. In the case where a change in the scroll speed is required, the indicator also provides the user with the opportunity to get used to changing the scroll speed in a shorter period of time (than) in previous systems.

2 is an illustrative flowchart illustrating operation in accordance with an embodiment of the present system. As shown, during step 210, the user initiates a scroll operation in the UI. This operation continues during action 220 for a period of time, which in an embodiment may be predetermined. During action 230, the system determines whether a scroll speed change is due. In the case where no change in scroll speed is to be made, the system returns to step 220, and the scrolling continues. In the case where the system determines, during step 230, that there is a change in the scroll speed, then during step 240, the user is provided with an indicator of the upcoming change in scroll speed. Upcoming - this means that at some point in time before changing the scroll speed, the user is provided with an indicator during action 250, which allows the user to stop either completely (no further scrolling, see steps 285 and 290), or simply continue with the current speed scroll, as shown during step 220. For example, the user can provide an indicator in the range of 0.1-2.0 seconds to change the scroll speed, although this range is not a required sign of this inventions. Obviously, what is coming can change for different applications and for different indicators (for example, an audio indicator as opposed to a vibration indicator, etc.).

In another embodiment, when the user stops activating the scrolling shortly after changing the speed, and then re-starts scrolling, the system may determine that this may indicate that the set notification period provided by the indicator is too short. If the user repeatedly repeats this behavior, the system can provide an indicator with a longer period of time until the scroll speed changes.

At step 280, it is determined whether the user's stop is complete. If the user does not stop, then during step 260 the scroll speed will change, and after that, during step 220, the scroll continues with the changed scroll speed. Obviously, although it is not shown, that at any time, when the user completely stops to activate the scroll, the system will perform actions 285, 290.

The indicator of the upcoming change in the scroll speed can take any touch form, including a tactile indicator, an auditory indicator, a visual indicator, etc. The term indicator used here means the content of, for example, a tactile indicator, an auditory indicator and / or visual indicator, unless otherwise specified. In some embodiments, the implementation of the UI visual indicator can be perceived as distracting the user from the visual perception of the scroll itself, which may have the opposite effect of the potential reason that the user will miss the desired target area in the visual environment. In this or other embodiments, the implementation of the UI indicator of a potential change in the scroll speed may be in the form of a tactile indicator and / or an auditory indicator, for example, vibration of the scroll wheel and / or tick.

In one embodiment, to reduce the need for the user to consciously assimilate the value of yet another application indicator, vibration, sound, and / or other sensory feedback, which is used to alert the user of an impending increase in scroll speed, may already be associated with scrolling. For example, in an application that presents a tick, each time a predetermined portion of the medium scrolls, before the scroll speed actually changes, the tick frequency may change, as shown in FIG. 3. Since the sound is aligned (for example, synchronized) with scrolling, a change in the tick frequency will warn the user, and he will think about an imminent change in the scroll speed. The user may then decide to respond to a change in the tick frequency during action 250, as shown in FIG.

Similarly, in an embodiment in which a scroll wheel or other scroll drive vibrates each time a part of the visual medium is scrolled, a change in the vibration frequency will alert the user and remind them of an imminent change in the scroll speed. Changing the vibration of the scroll drive in one embodiment may be initiated by a piezoelectric element operatively connected to the scroll drive. As is obvious to a person skilled in the art, similarly other touch indicators may be used.

Figure 3 shows how the speed of occurrence of the position, for example, the scroll speed and the speed of the indicator, which are depicted changing vertically, can vary depending on the duration of the scroll, which is shown changing horizontally. In particular, FIG. 3 depicts a graph 300 that depicts how, as the user continues to scroll over a period of time, the scroll speed can vary with a certain step from level 1 through level 2 to level 3, etc. A scroll speed comprising a change in scroll speed is depicted by a step function 310. According to an embodiment of the present system, a change in scroll speed is preceded by an indicator, which is illustratively shown by a step function 320. Step function 320 depicts an embodiment in which an indicator of an upcoming scroll speed change is provided by a change in speed indicator that precedes the change in scroll speed. For example, in a system that provides an indicator speed that is typically proportional to the scroll speed, in accordance with an embodiment of the present system, a change in the scroll speed is preceded by a change in the indicator speed to notify the user of an imminent upcoming change in the scroll speed.

When the user is warned and expects the scroll speed to change, the user can accept the change (see figure 2, steps 250 through steps 260, 220), or reject the change (see figure 2, steps 250 through steps 280, 220, or actions 280, 285, 290). Only in the latter case is a response required from the user. For example, a user may release the scroll drive to stop scrolling. When the user starts scrolling again, it can start from the initial speed identical to the previous one. Accordingly, the user effectively prevented the change in the scroll speed (but did not respond to it).

This kind of interaction is good for applications that have only two levels of scroll speed, but it can be ineffective for the user if the application has three or more levels of speed. Consider a user who prefers level 2 scroll speeds in an application. After some scrolling time at level 2 speed, the application further increases the scroll speed to level 3, a level that may not be preferable for the user. If the user then stops and re-starts scrolling, then each time the application can start again from level 1, which may be too slow for the user.

In one embodiment of the present system, in order to help the user not to start at the slowest scrolling speed each time, when the user stops actuating the scroll, the user may be able to stop the actuation even after a short time, before (expiration) of a certain predetermined time interval , resume operating again (e.g. release and quickly press the key or scroll wheel again). In this embodiment, if this is done in a row fast enough for the system (for example, before the expiration of a predetermined time interval), then the scroll speed may remain at the level at which it was at the time of termination of the actuation. In another similar embodiment, the scroll speed may return to some predetermined level (e.g., level 2) as opposed to returning to the initial level (e.g., level 1). In the case where the user waits a little longer (for example, after a predetermined time interval), scrolling can resume again at the speed of the initial level (for example, level 1).

In one embodiment, the present system can alleviate the burden of the user of the application repeatedly changing the scroll speed and the user forced to prevent the change, if required, by repeatedly stopping the activation of the scroll and quickly resuming the activation of the scroll. In this embodiment, the present system can establish, for example, by monitoring a user’s action over a period of time, that termination and rapid renewal implies that the user does not need to further change the scroll speed. In this embodiment, only when the user stops activating the scroll and waits long enough (for example, after a predetermined time) to resume, the system will again begin to change the scroll speed over time.

4, an apparatus 400 is shown in accordance with an embodiment of the present system. The device has a processor 410, operatively connected to the memory 420, a display 430, a scroll drive 470 and a device 440. The memory 420 may be any type of device for storing application data. Application data is received by processor 410 to configure processor 410 to perform operational actions in accordance with the present system. The operation steps comprise controlling at least one of the display 430 and the display 450 for displaying a UI that depicts a visual environment that is larger than the respective displays 430, 450. The scroll drive 470 operates on the processor 410 together with the drive application scroll as discussed above. A warning signal indicating an upcoming change in the scroll speed is generated by the processor 410 through the warning generator 460 and / or the scroll drive 470. A warning may comprise one or more of a tactile warning, an auditory warning, and a visual warning. The device 440 is operatively connected to the display 450, however, this device may simply be a display, for example a liquid crystal display (LCD) or a cathode ray tube (CRT). The device 440 may also perform other operations, including displaying television signals, displaying a gaming environment, displaying a CAD environment, etc. It is clear that only one display is required for operation, although both displays 430, 450 can also be used.

The embodiments described above are for illustration only and should not be construed as limiting the appended claims to any particular embodiment or group of embodiments. Numerous alternative embodiments can be devised by those skilled in the art without departing from the spirit and scope of the following claims.

In interpreting the appended claims, it should be understood that:

a) the word “comprising” does not exclude the presence of elements or actions other than those listed in this claim,

b) the use of an element in the singular does not exclude the presence of a plurality of such elements,

c) any reference positions in the claims do not limit their scope,

d) several "means" can be represented using the same element that implements a structure or function, either hardware or software,

e) any of the elements disclosed may consist of parts of hardware (e.g., including discrete and integrated electronic circuits), parts of software (e.g., automatic programming) and any combination thereof,

f) hardware parts may consist of one or both of the analog and digital parts,

g) any of the disclosed devices or parts thereof may be combined together or further divided into parts, unless expressly provided otherwise, and

h) no specific sequence of actions or steps is mandatory unless specifically indicated.

Claims (15)

1. The user interface of a device for displaying an environment that is visually larger than the display area, the user interface comprising:
a scroll function configured to place selected portions of the medium within the display area, wherein the scroll speed changes as the scroll function lasts, and
An indicator configured to alert the user of an impending change in scroll speed. 2. The user interface according to claim 1, in which the indicator is the first indicator, and the warning is the first warning, wherein the user interface comprises a second indicator that is configured to display a second warning to the user at a speed that is proportional to the scroll speed, and in which, when change in scroll speed, the second warning is replaced by the first warning. 3. The user interface according to claim 2, in which the first warning is displayed at a speed that is proportional to the scroll speed that is generated if the scroll speed changes. 4. The user interface according to claim 1, in which the warning is displayed for a predetermined time before changing the scroll speed. 5. The user interface according to claim 1, in which the warning is at least one of a tactile warning, auditory warning and visual warning. 6. The user interface according to claim 1, in which the warning is a vibration warning. 7. The user interface according to claim 6, in which the user interface is configured to generate a signal for the piezoelectric device to trigger a vibration warning. 8. The user interface according to claim 1, in which the warning is a clicking warning, and the user interface is configured to generate a signal for the hearing device to trigger a clicking warning. 9. The user interface according to claim 1, in which the scroll function is configured to initiate its first actuation of the scroll and configured so as not to change the scroll speed if the second actuation of the scroll within a predetermined time interval after the termination of the first actuation scroll. 10. The user interface according to claim 1, in which the scroll function is configured to initiate its first actuation of the scroll and configured to return to a predetermined scroll speed if the second actuation of the scroll within a predetermined time interval after the termination of the first actuation of the scroll . 11. A computer-readable storage medium (420) containing an application implemented on it, the application being configured to create a device user interface for displaying an environment that is visually larger than the display area according to any one of claims 1 to 10. 12. A device having a user interface for controlling a visual environment that is visually larger than the display area, this device comprising:
means for visually scrolling parts of the medium within the display area, wherein the scrolling speed changes as the scrolling function lasts, and
means for displaying an indicator to warn the user about an upcoming change in scroll speed. 13. The device according to item 12, in which the indicator is the first indicator, and the warning is the first warning, and this device contains means for displaying the second indicator to the user at a speed that is proportional to the scroll speed, and when the scroll speed is to be changed, to replace the second warning first warning. 14. The device according to item 12, in which the device contains means for creating an output for generating a warning, which is at least one of a tactile warning, auditory warning and visual warning. 15. The device according to item 12, in which the means for visual scrolling is configured to initiate its first actuation of the scroll and configured so as not to change the scroll speed if the second actuation of the scroll within a predetermined time interval after the termination of the first actuation a scroll action, or configured to return to a predetermined scroll speed if the second actuation of the scroll occurs within a predetermined interval in belt after the cessation of the first actuation of the scroll.

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